PULL FRAME INTERPOLATION
A method and apparatus for performing pull frame interpolation are provided. Pull frame interpolation may include identifying a plurality of input video frames, generating a plurality of motion vectors indicating motion from a first frame of the plurality of input video frames to a second frame of the plurality of input video frames, identifying an interpolation point between the first frame and the second frame, generating a plurality of candidate interpolation motion vectors indicating motion from the first frame to the interpolation point and from the second frame to the interpolation point based on the plurality of motion vectors, selecting an interpolation motion vector from the plurality of candidate interpolation motion vectors based on a metric, and generating an interpolated frame at the interpolation point based on the selected interpolation motion vector.
This application relates to video frame interpolation.
BACKGROUNDDigital video can be used, for example, for remote business meetings via video conferencing, high definition video entertainment, video advertisements, or sharing of user-generated videos. Accordingly, it would be advantageous to provide temporal and spatial frame interpolation.
SUMMARYDisclosed herein are aspects of systems, methods, and apparatuses for pull frame interpolation.
An aspect is a method for pull frame interpolation which may include identifying a plurality of input video frames, generating a plurality of motion vectors indicating motion from a first frame of the plurality of input video frames to a second frame of the plurality of input video frames, identifying an interpolation point between the first frame and the second frame, generating a plurality of candidate interpolation motion vectors indicating motion from the first frame to the interpolation point and from the second frame to the interpolation point based on the plurality of motion vectors, selecting an interpolation motion vector from the plurality of candidate interpolation motion vectors based on a metric, and generating an interpolated frame at the interpolation point based on the selected interpolation motion vector.
Another aspect is a method for pull frame interpolation which may include identifying a plurality of input video frames, generating a plurality of motion vectors indicating motion from a first frame of the plurality of input video frames to a second frame of the plurality of input video frames, determining a degree of smoothness of the plurality of motion vectors, using the first frame or the second frame as the interpolated frame on a condition that the degree of smoothness is above a threshold, and on a condition that the degree of smoothness is within the threshold identifying an interpolation point between the first frame and the second frame, jointly, using a combined energy function, identifying an occlusion and generating, based on the plurality of motion vectors, a plurality of candidate interpolation motion vectors that includes a candidate interpolation motion vectors indicating motion from the first frame to the interpolation point, a candidate interpolation motion vectors indicating motion from the second frame to the interpolation point, and a candidate interpolation motion vector based on motion prediction for a plurality of adjacent sites. For each interpolation site in a plurality of interpolation sites, pull frame interpolation may include selecting an interpolation motion vector from the plurality of candidate interpolation motion vectors based on smoothness constraints within the interpolated frame and on smoothness constraints between the first frame and the second frame, and selecting an interpolation motion vector and updating the interpolated frame based on the selected interpolation motion vector. Pull frame interpolation may include generating an interpolated frame at the interpolation point based on the selected interpolation motion vector, wherein the interpolated frame includes the plurality of interpolation sites, wherein generating the interpolated frame includes correcting an artifact in the interpolated frame based on the interpolation motion vector by blending the interpolated frame with an average of the first frame and the second frame, wherein the degree of blending is based on a gradient of a motion field associated with the interpolation motion vector, such that a portion of the interpolated frame that has a high motion gradient is replaced with a corresponding area of the average of the first frame and the second frame.
Variations in these and other aspects will be described in additional detail hereafter.
The description herein makes reference to the accompanying drawings wherein like reference numerals refer to like parts throughout the several views, and wherein:
Digital video may be used for various purposes including, for example, remote business meetings via video conferencing, high definition video entertainment, video advertisements, and sharing of user-generated videos. The generation and display of a video signal may be performed at different frame rates. Pull frame interpolation may be performed to convert from one frame rate to another or to generate temporal or spatial video effect, such as a slow motion effect.
Video signal generation may include generating a video signal in an analog or digital format. Some formats may include interlaced images of two fields each, wherein half of the lines available in each frame are sampled at each time instant (or frame sampling period). The number of frames per time unit (frame rate) may vary and conversion may be performed to convert from one frame rate to another. Non-motion compensated frame rate conversion, which may be based on dropping or repeating frames, may not preserve motion well. Motion compensated frame rate conversion, such as frame interpolation, which may better preserve motion, may include generating new, interpolated, frames using motion information from the video signal.
Pull frame interpolation may be used for frame rate conversion. In some implementations, pull frame interpolation may be used to generate temporal or spatial video effects. For example, pull frame interpolation may generate additional frames to transition into and out of a slow motion effect, or to interpolate frames between spatially proximate input frames to produce a space-move effect.
Pull frame interpolation may include generating interpolated frames using motion information pulled from consecutive existing frames. The motion information may be generated by any motion estimator. Interpolated motion may be generated independently of picture interpolation. Pull frame interpolation may include optimization based on candidate motion vector selection. Post-processing may be performed to, for example, improve handling of blur or low quality input data. In some implementations, pull frame interpolation may include using a multiresolution multipass scheme to improve performance of, for example, input including large amounts of motion.
The computing device 100 may be a stationary computing device, such as a personal computer (PC), a server, a workstation, a minicomputer, or a mainframe computer; or a mobile computing device, such as a mobile telephone, a personal digital assistant (PDA), a laptop, or a tablet PC. Although shown as a single unit, any one or more element of the communication device 100 can be integrated into any number of separate physical units. For example, the UI 130 and processor 140 can be integrated in a first physical unit and the memory 150 can be integrated in a second physical unit.
The communication interface 110 can be a wireless antenna, as shown, a wired communication port, such as an Ethernet port, an infrared port, a serial port, or any other wired or wireless unit capable of interfacing with a wired or wireless electronic communication medium 180.
The communication unit 120 can be configured to transmit or receive signals via a wired or wireless medium 180. For example, as shown, the communication unit 120 is operatively connected to an antenna configured to communicate via wireless signals. Although not explicitly shown in
The UI 130 can include any unit capable of interfacing with a user, such as a virtual or physical keypad, a touchpad, a display, a touch display, a speaker, a microphone, a video camera, a sensor, or any combination thereof. The UI 130 can be operatively coupled with the processor, as shown, or with any other element of the communication device 100, such as the power source 170. Although shown as a single unit, the UI 130 may include one or more physical units. For example, the UI 130 may include an audio interface for performing audio communication with a user, and a touch display for performing visual and touch based communication with the user. Although shown as separate units, the communication interface 110, the communication unit 120, and the UI 130, or portions thereof, may be configured as a combined unit. For example, the communication interface 110, the communication unit 120, and the UI 130 may be implemented as a communications port capable of interfacing with an external touchscreen device.
The processor 140 can include any device or system capable of manipulating or processing a signal or other information now-existing or hereafter developed, including optical processors, quantum processors, molecular processors, or a combination thereof. For example, the processor 140 can include a general purpose processor, a special purpose processor, a conventional processor, a digital signal processor (DSP), a plurality of microprocessors, one or more microprocessor in association with a DSP core, a controller, a microcontroller, an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA), a programmable logic array, programmable logic controller, microcode, firmware, any type of integrated circuit (IC), a state machine, or any combination thereof. As used herein, the term “processor” includes a single processor or multiple processors. The processor can be operatively coupled with the communication interface 110, communication unit 120, the UI 130, the memory 150, the instructions 160, the power source 170, or any combination thereof.
The memory 150 can include any non-transitory computer-usable or computer-readable medium, such as any tangible device that can, for example, contain, store, communicate, or transport the instructions 160, or any information associated therewith, for use by or in connection with the processor 140. The non-transitory computer-usable or computer-readable medium can be, for example, a solid state drive, a memory card, removable media, a read only memory (ROM), a random access memory (RAM), any type of disk including a hard disk, a floppy disk, an optical disk, a magnetic or optical card, an application specific integrated circuits (ASICs), or any type of non-transitory media suitable for storing electronic information, or any combination thereof. The memory 150 can be connected to, for example, the processor 140 through, for example, a memory bus (not explicitly shown).
The instructions 160 can include directions for performing any method, or any portion or portions thereof, disclosed herein. The instructions 160 can be realized in hardware, software, or any combination thereof. For example, the instructions 160 may be implemented as information stored in the memory 150, such as a computer program, that may be executed by the processor 140 to perform any of the respective methods, algorithms, aspects, or combinations thereof, as described herein. The instructions 160, or a portion thereof, may be implemented as a special purpose processor, or circuitry, that can include specialized hardware for carrying out any of the methods, algorithms, aspects, or combinations thereof, as described herein. Portions of the instructions 160 can be distributed across multiple processors on the same machine or different machines or across a network such as a local area network, a wide area network, the Internet, or a combination thereof.
The power source 170 can be any suitable device for powering the communication device 110. For example, the power source 170 can include a wired power source; one or more dry cell batteries, such as nickel-cadmium (NiCd), nickel-zinc (NiZn), nickel metal hydride (NiMH), lithium-ion (Li-ion); solar cells; fuel cells; or any other device capable of powering the communication device 110. The communication interface 110, the communication unit 120, the UI 130, the processor 140, the instructions 160, the memory 150, or any combination thereof, can be operatively coupled with the power source 170.
Although shown as separate elements, the communication interface 110, the communication unit 120, the UI 130, the processor 140, the instructions 160, the power source 170, the memory 150, or any combination thereof can be integrated in one or more electronic units, circuits, or chips.
A computing and communication device 100A/100B/100C can be, for example, a computing device, such as the computing device 100 shown in
Each computing and communication device 100A/100B/100C can be configured to perform wired or wireless communication. For example, a computing and communication device 100A/100B/100C can be configured to transmit or receive wired or wireless communication signals and can include a user equipment (UE), a mobile station, a fixed or mobile subscriber unit, a cellular telephone, a personal computer, a tablet computer, a server, consumer electronics, or any similar device. Although each computing and communication device 100A/100B/100C is shown as a single unit, a computing and communication device can include any number of interconnected elements.
Each access point 210A/210B can be any type of device configured to communicate with a computing and communication device 100A/100B/100C, a network 220, or both via wired or wireless communication links 180A/180B/180C. For example, an access point 210A/210B can include a base station, a base transceiver station (BTS), a Node-B, an enhanced Node-B (eNode-B), a Home Node-B (HNode-B), a wireless router, a wired router, a hub, a relay, a switch, or any similar wired or wireless device. Although each access point 210A/210B is shown as a single unit, an access point can include any number of interconnected elements.
The network 220 can be any type of network configured to provide services, such as voice, data, applications, voice over internet protocol (VoIP), or any other communications protocol or combination of communications protocols, over a wired or wireless communication link. For example, the network 220 can be a local area network (LAN), wide area network (WAN), virtual private network (VPN), a mobile or cellular telephone network, the Internet, or any other means of electronic communication. The network can use a communication protocol, such as the transmission control protocol (TCP), the user datagram protocol (UDP), the internet protocol (IP), the real-time transport protocol (RTP) the Hyper Text Transport Protocol (HTTP), or a combination thereof.
The computing and communication devices 100A/100B/100C can communicate with each other via the network 220 using one or more a wired or wireless communication links, or via a combination of wired and wireless communication links. For example, as shown the computing and communication devices 100A/100B can communicate via wireless communication links 180A/180B, and computing and communication device 100C can communicate via a wired communication link 180C. Any of the computing and communication devices 100A/100B/100C may communicate using any wired or wireless communication link, or links. For example, a first computing and communication device 100A can communicate via a first access point 210A using a first type of communication link, a second computing and communication device 100B can communicate via a second access point 210B using a second type of communication link, and a third computing and communication device 100C can communicate via a third access point (not shown) using a third type of communication link. Similarly, the access points 210A/210B can communicate with the network 220 via one or more types of wired or wireless communication links 230A/230B. Although
Other implementations of the computing and communications system 200 are possible. For example, in an implementation the network 220 can be an ad-hock network and can omit one or more of the access points 210A/210B. The computing and communications system 200 may include devices, units, or elements not shown in
The encoder 400 can encode an input video stream 402, such as the video stream 300 shown in
For encoding the video stream 402, each frame within the video stream 402 can be processed in units of blocks. Thus, a current block may be identified from the blocks in a frame, and the current block may be encoded.
At the intra/inter prediction unit 410, the current block can be encoded using either intra-frame prediction, which may be within a single frame, or inter-frame prediction, which may be from frame to frame. Intra-prediction may include generating a prediction block from samples in the current frame that have been previously encoded and reconstructed. Inter-prediction may include generating a prediction block from samples in one or more previously constructed reference frames. Generating a prediction block for a current block in a current frame may include performing motion estimation to generate a motion vector indicating an appropriate reference block in the reference frame.
The intra/inter prediction unit 410 may subtract the prediction block from the current block (raw block) to produce a residual block. The transform unit 420 may perform a block-based transform, which may include transforming the residual block into transform coefficients in, for example, the frequency domain. Examples of block-based transforms include the Karhunen-Loéve Transform (KLT), the Discrete Cosine Transform (DCT), and the Singular Value Decomposition Transform (SVD). In an example, the DCT may include transforming a block into the frequency domain. The DCT may include using transform coefficient values based on spatial frequency, with the lowest frequency (i.e. DC) coefficient at the top-left of the matrix and the highest frequency coefficient at the bottom-right of the matrix.
The quantization unit 430 may convert the transform coefficients into discrete quantum values, which may be referred to as quantized transform coefficients or quantization levels. The quantized transform coefficients can be entropy encoded by the entropy encoding unit 440 to produce entropy-encoded coefficients. Entropy encoding can include using a probability distribution metric. The entropy-encoded coefficients and information used to decode the block, which may include the type of prediction used, motion vectors, and quantizer values, can be output to the compressed bitstream 404. The compressed bitstream 404 can be formatted using various techniques, such as run-length encoding (RLE) and zero-run coding.
The reconstruction path can be used to maintain reference frame synchronization between the encoder 400 and a corresponding decoder, such as the decoder 500 shown in
Other variations of the encoder 400 can be used to encode the compressed bitstream 404. For example, a non-transform based encoder 400 can quantize the residual block directly without the transform unit 420. In some implementations, the quantization unit 430 and the dequantization unit 450 may be combined into a single unit.
The decoder 500 may receive a compressed bitstream 502, such as the compressed bitstream 404 shown in
The entropy decoding unit 510 may decode data elements within the compressed bitstream 502 using, for example, Context Adaptive Binary Arithmetic Decoding, to produce a set of quantized transform coefficients. The dequantization unit 520 can dequantize the quantized transform coefficients, and the inverse transform unit 530 can inverse transform the dequantized transform coefficients to produce a derivative residual block, which may correspond with the derivative residual block generated by the inverse transformation unit 460 shown in
Other variations of the decoder 500 can be used to decode the compressed bitstream 502. For example, the decoder 500 can produce the output video stream 504 without the deblocking filtering unit 570.
The top timeline 610 shows an example of frame rate conversion wherein the output frame rate may be a multiple, such as three, of the input frame rate. For example, as shown, the input frame rate may be 25 frames per second (fps) and the output frame rate may be 75 fps. As shown, one third of the interpolated frames 604 coincide with the original frames 602 and the remaining two thirds of the interpolated frames 604 may be in-between the original frames 602. The output may be presented at the input frame rate of 25 fps, which may produce a slow motion effect that may appear slowed down by a factor of three. A slow motion factor of three is described as an example; however, any other slow motion factor may be used.
The middle timeline 620 shows an example of frame rate conversion wherein the input frame rate may be 25 fps and the output frame rate may be 30 fps. As shown, the locations of the output frames 604 may not be evenly spaced relative to the input frames 602. The location pattern of the output frames 604 may have a periodicity that can be used for the creation of the interpolated frames 604.
The bottom timeline 630 shows an example of frame rate conversion wherein the input frame rate may be 25 fps and the output frame rate may be 50 fps, and wherein the output frame rate transitions linearly from 25 fps to 50 fps. For example, the output video sequence may show a deceleration in time, or a slow motion effect. In this last case there may not be a simple periodicity to the output frame location in time.
In some implementations, conversion between one frame or field rate and another may include non-motion compensating conversion, which may include repeating frames, as in zero-order hold conversion, or dropping frames, as in subsampling conversion. For example, converting 30 fps (60 fields per second) interlaced video to 25 fps (50 fields per second) interlaced video may include dropping 50 fields out of every 300 fields from the 30 fps source. Thus, one field may be dropped for every six fields from the source. Convert from 25 fps interlaced to 30 fps interlaced may include repeating one field in every six from the source. Dropping or repeating fields produce low quality converted pictures wherein one frame in every six may have a wrong field merged into a frame. That may result in poorly represented motion, which may be perceived like a stutter effect in the converted material. In some implementations, a missing field may be estimated by interpolating it from the given video data. For example, at a given time, an odd field may be estimated from an even field by averaging lines vertically. In a subsequent time, the estimated field may be repeated or an original field may be dropped.
Non-motion compensating conversion may not preserve motion well. For example, a large amount of motion, such as motion of five pixels per frame, may not be well preserved. Conversion to progressive formats or between progressive formats may not preserve motion well. In some implementations, conversion may include motion compensated techniques that use motion information derived from the video data. Motion compensated conversion may include interpolating new fields or frames by directing the interpolation along motion trajectories. Motion compensated conversion may include handling occlusion, wherein a portion of a frame is hidden in one frame and visible in another. A portion of a frame that is occluded, in one frame or another, may not be available for use in conversion.
In some implementations, motion compensation may be performed by dedicated motion compensation hardware, such as circuitry. For example, real time conversion may be implemented using motion compensation circuitry. Hardware based motion compensation may have relatively limited complexity compared to motion compensation implemented in software or in a combination of hardware and software.
In some implementations, motion compensation may be implemented in software, such as post-production software. For example, software based conversion may be used to create slow-motion effects in videos, such as movies and cinemas. Software based non-real-time conversion may include interpolating frames at arbitrary points in time or space. Thus, conversion may include decelerating a frame rate to create a slow-motion effect, and accelerate the frame rate to transition out of the slow-motion effect.
In some implementations, conversion may include interpolating among non-temporally sequential frames. For example, spatially sequential frames may be interpolated to create an effect, such as a smooth space-move effect. In some implementations, spatially sequential frames may be captured concurrently, or near concurrently.
In some implementations, image data from existing frames may be pushed into interpolated frames along contours of least gradient between relevant images. Push interpolation may include copying pixel values from existing frames into interpolated frames. Push interpolation may produce convincing frame interpolation, but may not be optimal along directions of motion. For example, the motion fidelity of the conversion may not be accurate when an input video sequence is viewed at the target frame rate.
In some implementations, frame interpolation may include recovering missing frames in archived motion picture film and video footage. Frame interpolation for frame recovery may include reconstructing a frame at an arbitrary time instant by recovering the motion field at that instant.
For example, the first input frame 710 may capture the scene at a first point in time T1, the second input frame 720 may capture the scene at a second point in time T2, and the third input frame 730 may capture the scene at a third point in time T3. The first interpolated frame 750 may interpolate the scene at a point in time between the first point in time T1 and the second point in time T2, and the second interpolated frame 760 may interpolate the scene at a point in time between the second point in time T2 and the third point in time T3.
In some implementations, pull frame interpolation may include generating a time-stop or timeslice effect, wherein a camera may appear to move through space and wherein time may appear to slow or stop. For example, a time-stop effect may be generated using frames recorded concurrently by multiple cameras placed at multiple different spatial positions during a time period. The first input frame 710 may capture the scene at a first point in space T1, the second input frame 720 may capture the scene at a second point in space T2, and the third input frame 730 may capture the scene at a third point in space T3. The input frames 710/720/730 may be capture the scene at the same, or substantially the same point in time. The first interpolated frame 750 may interpolate the scene at a point in space between the first spatial point T1 and the second spatial point T2, and the second interpolated frame 760 may interpolate the scene at a point in space between the second spatial point T2 and the third spatial point T3. The interpolated frames 750/760 may be associated with the same, or substantially the same, point in time as the input frames 710/720730.
Occluded areas 770 of the scene, such as a background, that may be hidden by the object 740 in a frame and uncovered in a subsequent frame are shown using cross hatching. Uncovered areas 780 of the scene that may be shown in a frame and occluded in a subsequent frame are shown using stippling. A motion trajectory line 790 is also shown. In some implementations, pull frame interpolation may include preserving occluded areas 770, uncovered areas 780, and the motion trajectory 790.
In some implementations, pull frame interpolation may include estimating pixel intensities in the interpolated frames 750/760 based on the data in the input frames 710/720/730. Motion information may be used to copy pixel intensities from the input frames 710/720/730 into the locations interpolated along the direction of motion, thus building up the interpolated frames 750/760 pixel by pixel. Pixels in the occluded regions 770 may not be available for use in subsequent frames. Pixels in uncovered regions 780 may not be available for use in previous frames.
The input frames 810/812/814/816 may include a scene captured as a spatial or temporal sequence. For example, the first input frame 810 may capture the scene at a first point in time t, the second input frame 812 may capture the scene at a subsequent point in time t+1, the third input frame 814 may capture the scene at another subsequent point in time t+2, and the fourth input frame 816 may capture the scene at a previous point in time t−1. In another example, the first input frame 810 may capture the scene at a first point in space t, the second input frame 812 may capture the scene at a subsequent point in space t+1, the third input frame 814 may capture the scene at another subsequent point in space t+2, and the fourth input frame 816 may capture the scene at a previous point in space t−1. The interpolated frame 800 may be generated at a point t+Δ between the first frame 810 at t and the second frame 812 at t+1. Although one interpolated frame is shown, any number of interpolated frames may be generated at points between the first frame 810 and the second frame 812.
The interpolated frame 800 may be offset from the first input frame 810 at t by a time or space interval Δ, and from the second input frame 812 at t+1 by 1−Δ. An element of the captured scene, such as an object, is shown as a rectangle translating uniformly along the frames. For example, the object is shown at a first location 820 in the frame 816 at t−1, at a second location 822 in the frame 810 at t, at a third location 824 in the frame 812 at t+1, and at a fourth location 826 in the frame 814 at t+2. Although the object is shown as moving within the frames, the object may be stationary, or substantially stationary, within the frame and other elements of the scene, such as the background, may move relative to the object. An interpolated location 830 for the object is shown as a broken line rectangle at the interpolated frame 800 at t+Δ.
In some implementations, pull frame interpolation may include using motion estimation information, which may be generated independently of the pull frame interpolation. For example, any motion estimation technique may be used to generate motion estimation information prior to pull frame interpolation. Motion between the frame 810 at t and the frame 812 at t+1 at position x may be expressed as dt,t+1(x)=[d1; d2] where d1 and d2 indicate the horizontal and vertical components of the motion. The intensity of a pixel at x in frame t may be expressed as It(x). The location of the motion compensated pixel in the previous frame may be expressed as It−1(x+dt,t−1(x)).
The motion of the object between the frame 814 at t−1 and the frame 810 at t, which may be expressed as dt,t−1, is shown using an example motion vector 840. The motion of the object between the frame 810 at t and the frame 812 at t+1, which may be expressed as dt,t+1, is shown using another example motion vector 842. Background motion between the frame 812 at t+1 and the frame 810 at t, which may be expressed as dt+1,t, is shown using an example zero motion vector 844. Background motion between the frame 812 at t+1 and the frame 814 at t+2, which may be expressed as dt+1,t+2, is shown using another example motion vector 846.
The interpolated motion between the interpolated frame 800 at t+Δ and the frame 810 at t may be expressed as dt+Δ,t, and the interpolated motion between the interpolated frame 800 at t+Δ and the frame 812 at t+1 may be expressed as dt+Δ,t+1.
In some implementations, pull frame interpolation may include using occlusion state information. The occlusion state information may include an occlusion state associated with each pixel in a frame. For example, the occlusion state associated with the pixel at position x of frame t may be expressed as st(x)=[00; 01; 10], wherein st(x)=00 indicates that the pixel is not occluded in the next and previous frames, st(x)=01 indicates that the pixel is occluded in the next frame (forward occlusion), and st(x)=10 indicates that the pixel is occluded in the previous frame (backward occlusion). The association of each position in the interpolated frame 800 at t+Δ with an occlusion state is indicated at t+Δ using crosshatching and stippling respectively. The occlusion state of the interpolated image data corresponding to content of the scene which exists in the frame 810 at t and the frame 812 at t+1 may be expressed as s=00. The occlusion state of the interpolated image data corresponding to the patch which does not exist, or is occluded, in the frame 810 at t and exists, or is uncovered, in the frame 812 at t+1 may be expressed as s=10. The occlusion state of the interpolated image data corresponding to the patch which exists in the frame 810 at t and does not exist, or is occluded, in the frame 812 at t+1 may be expressed as s=01.
In some implementations, a pull frame interpolation model may be expressed as the following:
Pull frame interpolation may include estimating motion fields between the interpolated frame 800 at t+Δ and the input frame 810 at t, and between the interpolated frame 800 at t+Δ and the input frame 812 at t+1, and may include estimating the states of the pixels st+Δ(x). Interpolating motion at t+Δ may be referred to as a pull process, and may include using the motion at the interpolated frame 800 at t+Δ to pull pixels from the input frame 810 at t and the input frame 812 at t+1 to create the image It+Δ using Equation 2.
In some implementations, D, i may include existing motion estimates and image data, d—(X) may collect motion in the interpolated frame in proximity to a current site, and manipulating the posterior probability distribution p(dt+Δ;t+1, dt+Δ,t|D, i) in a Bayesian fashion may be expressed as the following:
The estimate for dt+δ, used as the interpolated motion, may maximize the posterior in Equation 2.
In some implementations, pull frame interpolation may include using image likelihood. Image likelihood may be used such that eI(x)=It(x+dt+Δ,t)−It+1(x+dt+Δ,t+1) may indicate the motion compensated motion compensated pixel difference between the pixel in the next frame and the pixel in the previous frame. For example, an image may be a color image, and eI may be is a vector of three differences corresponding to the three color planes. In some implementations, the interpolated motion may be accurate and the differences corresponding to the three color planes may be small unless occlusion occurs.
In some implementations, image data at t+Δ may not be known a-priori and, motion may be used to explicitly incorporate s(•), which may be expressed as follows:
In some implementations, kI may equal 10×2.72 to allow for a strong bias away from occlusion in the image data. In color images eI2 may be the scaled vector magnitude, such as the average of the square of the three difference components. In some implementations, σI2 can be measured from the pixel data or may be set to 1:0.
In some implementations, pull frame interpolation may include motion likelihood. Motion likelihood may be used such that the true interpolated motion may agree with the motion already estimated between the existing frames. Pull frame interpolation may include maximizing motion agreement by encouraging motion compensated motion differences to be small. Encouraging motion compensated motion differences to be small may include expressing the motion compensated motion differences as follows:
In Equations 4-8, the x argument in the interpolated motion fields dt+Δ is omitted for clarity.
In some implementations, s(•) may be incorporated and the motion likelihood may be expressed as follows:
In Equation 9 α may represent penalty energies that may balance the loss of temporal continuity in occluded states 10, 01 and discourage the occurrence of occluded states. ed may penalize motion vector pairs which show acceleration. The motion likelihood for state s(•)=00 may encourage the interpolated motion to align with existing motion between frames t,t−1; t,t+1; t+1, t+2. In the other states (01; 10) temporal smoothness may be encouraged with motion between t,t−1 and t=1,t+2 respectively.
In some implementations, pull frame interpolation may include using motion priors. In an example, the motion fields may be Markov Random Fields. A motion prior may consists of two factors, pd(•) which may enforce spatial smoothness of the estimated motion field, and pg(•) which may penalize large deviations in the motion field from a pre-computed estimate for global motion. Spatial smoothness of the interpolated motion fields may be enforced using the usual Gibbs energy prior which may be expressed as follows:
Motion in the opposite direction may be expressed similarly. In Equation 10, Λd may control the strength of the smoothness. For example, Λd=2.0 may be used. The contribution from each of the clique terms may be weighted with λk inversely with their distance from x. For example, λk=1/|vk| may be used. In some implementations, K may be eight, such that the eight pixels proximate to the current pixel may be indexed with vk.
As shown in
In some implementations, dg may be a pre-computed estimate for the global (or camera) motion of the interpolated frames, f(•) may be a robust function, such as the function expressed in Equation 11, and pg(•) may be expressed as follows:
pg(dt+Δ,t|dg)∝exp−Λgf(dt+Δ,t(x)−dg). [Equation 12]
In some implementations, the motion in the current frame may be encouraged to ‘snap’ to the global motion of the camera when sensible. In some implementations, a low strength constraint, such as Λg=01, may be employed. In some implementations, the constraint may be turned off for robustness, such as Λg=0.
In some implementations, pull frame interpolation may include using occlusion priors. A prior for occlusion p(s(•) may encourage spatial smoothness in the estimated states and may be expressed as the following:
In Equation 13, h(s1; s2) may be an energy function that assigns energies according to the state pairs (S1; s2) which may be expressed as follows:
The energy function expressed in Equation 13 may discourage occlusion states 01 and 10 from sharing a boundary and may encourage the states to be the same in proximity. The energy function may encourage spatial smoothness in the occlusion states, such as in a group of proximate pixels. For example, the states of the eight pixels proximate to a current pixel are 01, the energy function may encourage the state at the current site to be the 01. In another example, the states of five sites around a current site may be 00, and the energy function may encourage the current site to be 00, which may produce in the smoothest configuration in the local area.
The energy function also serves to prevent 01 and 10 from being close together in that 8 nearest neighbourhood.
The energy function expressed in Equation 13 may be used to identify the unknown motion dt+Δ, which may include optimizing Equation 2 using, for example, Graph Cuts, Belief Propagation or any other local update scheme.
In some implementations, pull frame interpolation may include optimization. The computational load of pull frame interpolation may be reduced by proposing local candidates for the interpolated motion using temporal motion prediction techniques, and using the energy function expressed in Equation 13 to select an optimized candidates at each site. Motion and occlusion may be jointly estimated, rather than estimating for each in turn. The optimization process may be iterated until conclusion. In some implementations, the optimization may include Iterated Conditional Modes (ICM) optimization combined with local importance sampling. In some implementations, to facilitate candidate generation, optimization may include motion estimation, temporal hit list generation, initial estimate generation, or any combination thereof. Although described herein as elements of pull frame interpolation motion estimation, temporal hit list generation, and initial estimate generation may be performed independently prior to pull frame interpolation.
As shown in
In some implementations, generating a hit list may include identifying forward hits by scanning every vector dt,t+1(x) for all x in the frame 810 at t, and, at each site x+Δdt,t+1(x) in the frame 800 at t+Δ, storing an indication, such as a record, of dt,t+1(x), which may indicate a hit at that site.
In some implementations, generating a hit list may include identifying backward hits by scanning every vector dt+1,t(x) for each x in the frame 820 at t+1, and, at each site x+(1−Δ)dt+1,t(x) in the frame 800 at t+Δ, storing an indication, such as a record, of dt+1,t(x), which may indicate a hit at that site.
The forward hits and the backward hits may be two co-located lists, Cb/T, Cf/T, of candidate interpolation motion vectors (pointing in the forward and backward temporal directions) for every site in the interpolated frame at t+Δ. In some implementations, the motion fields may include inaccuracies, the handling occlusion may be difficult, and the hit list generation may include sites at which there is more than one hit in each list, or no hits.
In some implementations, input frames, such as the input frames 810/812/814/816 shown in
In some implementations, motion may be generated for input frames at 1110. For example, motion fields may be computed between frame pairs t, t−1; t, t+1; t+1, t; t+1, t+2. Any motion estimation (prediction) process can be used, such as block matching or optic flow motion estimation. The motion fields may be used to initialize dt;t+1; dt;t+1; dt+1;t−1; dt+1;t+2 respectively. The motion fields may remain constant during interpolation.
In some implementations, motion smoothness may be determined at 1120. Determining motion smoothness may include determining whether the motion smoothness is low at 1122, repeating an input frame as the interpolated frame at 1124, or both. The motion fields between the existing frames of some scenes, such as badly illuminated scenes or scenes shot with a low original frame rate that include high motion content, may not be temporally or spatially consistent (low motion smoothness) and generation of a high quality interpolated frame may be unlikely. For frames exhibiting low motion smoothness an input frame, such as the frame at t or the frame at t+1, may be repeated as the interpolated frame.
Identifying temporal or spatial inconsistency (low motion smoothness) at 1122 may include determining the motion compensated motion difference between frames t and t+1 in blocks that tile the frame evenly. A grid of three blocks horizontally and two blocks vertically may be used with the block sizes scaled to tile the image frame accordingly. Each block may include B1×B2 sites, B may include the sites x in block b, and calculating the motion compensated motion differences in a block b, emb may be expressed as follows:
In Equation 15, the x in dt,t+1(x) is omitted for simplicity. The motion compensated motion differences may be above a smoothness constraint or threshold and an input frame such as the frame at t or the frame at t+1, may be repeated as the interpolated frame at 1124.
A motion compensated motion difference emb that exceeds a threshold (constraint) δb may indicate that the motion information is unreliable and an input frame such as the frame at t or the frame at t+1, may be repeated as the interpolated frame at 1124. In some implementations, the repeated input frame may be identified based on proximity to the interpolated frame Δ. For example, Δ may be less than or equal to 0.5 and the frame at t may be repeated. In another example, Δ may be greater than 0.5 and the frame at t+1 may be repeated. In some implementations, Δ may be greater than or equal to 0.5 and the frame at t+1 may be repeated.
In some implementations, identification of motion as consistent motion may change smoothly with the size of the frames in the video sequence. For example, a large threshold may be used for high definition pictures and a low threshold may be used for low resolution pictures. In some implementations, the threshold δb may be proportional to the horizontal size of the image in pixels Nh. For example, the threshold δb may be 50×Nh/1920.
In some implementations, candidate interpolation motion vectors (hits) may be generated at 1130. A list of candidate interpolation motion vectors (hit list) for the interpolated frame may be based on the motion identified for the input frames. For example, the hit list may be generated as shown in
In some implementations, output information may be initialized at 1140. For example, initializing the output information may include using random assignment, hit list based assignment, or a combination thereof. In some implementations, a quick initial estimate of the interpolated motion field may be generated using the hit list. In some implementations, NTb(x) may indicate the number of temporal candidates (hits) in the backward direction and NTf(x) may indicate the number of temporal candidates (hits) in the forward direction. The initial estimation may include scanning the sites in t+Δ. The number of hits may be such that NTb(x)==1) && (NTf(x)==1), the motion in the lists may be assigned to the interpolated motion, and s may be set to 00. The number of hits may be such that NTb(x)≧1) && (NTf(x)==0), a first motion hit in the backward direction may be assigned to both directions of interpolated motion, and s may be set to 10. The number of hits may be such that NTb(x)==0) && (NTf, (x)≧1), a first motion hit in the forward direction may be assigned to both directions of interpolated motion, and s may be set to 01. Otherwise the interpolated motion may be set to 0 and s may be set to 00. Initializing the output information may include setting an iteration counter to zero.
In some implementations, local site updates may be performed at 1150. Performing local site updates may include selecting and updating an interpolation motion vector for each site in the interpolation frame. Local site updates may be performed iteratively for each site in the interpolated frame.
In some implementations, performing local site updates may include identifying candidate interpolation motion vectors in the forward and backward directions using the hit list generated at 1130. The hit list may be empty and no forward or backwards hits may be identified. Motion at the eight proximate neighbors of the current site, as shown in
In some implementations, performing local site updates may include assigning the motion candidate pair having the lowest energy to the interpolated motion field, which may include replacing values currently in that field. For that candidate the state value s may be indicated by the minimal energy. For example, if E00 has minimal energy, then s=00.
In some implementations, performing local site updates may include removing isolated occlusion states at 1152, estimating global motion at 1154, or both.
Removing isolated occlusion states at 1152 may include detecting occurrences of sites at which s(x) is not equal to s(vk+x) and s(vk+x) are all the same, and replacing s(•) with the value of the neighbors. The motion at the site may be replaced with the average motion of its neighbors. Removing isolated occlusion states may reduce the occurrence of impulsive single site artifacts.
Estimating global motion at 1154 may be performed if all sites have been visited. Estimating global motion of the new estimate for the interpolated motion field may include using a global motion estimation method based on using dense motion flow. For example, the most frequently occurring motion vector, the average of all the vectors, or a polynomial fit to the vector field, may be used as the global motion of the scene.
In some implementations, whether to build the interpolated frame may be determined at 1160. Performing local site updates at 1150 may include iterating the iterations counter. If the iterations counter exceeds a threshold, such as five, the interpolated frame may be built at 1170. In some implementations, if there has been no change in any estimated motion, the interpolated frame may be built at 1170. If the iterations counter is within the threshold, there has been a change in estimated motion, or both, initializing output information at 1140, performing local site updates at 1150, and determining whether to build the interpolated frame at 1160 may be iteratively performed.
In some implementations, an interpolated frame may be built at 1170. Building the interpolated frame may include using the estimated motion and may be based on Equation 2.
In some implementations, post processing may be performed at 1180. Due to difficulty in estimating motion when that motion is fast, or the recording was taken in low light, post-processing may be performed to reduce or correct the appearance of image artifacts. These artifacts may appear as holes in the image It+Δ, or strange warping of the image near large occluded or uncovered regions. Low confidence image estimates may be identified and may be blended seamlessly with the average of the future and past frames. A gradient of the motion field may be used, which may include choosing forward or backward direction depending on which is greater, as the measure of confidence in the interpolation.
Post-processing may include generating a conservative estimate for the interpolated frame using averaging I*(x)=(1−Δ)It(x)+Δft+1(x). For simplicity, the backward interpolated motion dt+Δ,t−1(x) may be expressed as [{circumflex over (d)}1b(h, k), {circumflex over (d)}2b(h, k)] and the forward interpolated motion dt+Δ,t(x) may be expressed as [{circumflex over (d)}1f(h, k), {circumflex over (d)}2f(h, k)] where x=[h,k]. Measuring the motion gradient gm(x) at each site x and blending weight w(x) may be expressed as follows:
For example, δt=4 may be used.
A final output picture may be calculated using Î(x)=w(x)I*(x)+(1−w(x))It+Δ(x), which may be a weighted blend between the non-motion compensated average picture I* and the output picture from the previous stage It+Δ. In some implementations, an interpolated frame may be output at 1190.
Equation 1 is shown as an example and other reconstruction methods may be used, such as a median (or other order statistic) operation on a volume of pixels extracted around them motion compensated sites in the previous and next frames.
Although not shown in
In some implementations, input frames may be identified at 1210. Identifying input frames may identifying frames, such as the input frames 810/812/814/816 shown in
In some implementations, motion vectors may be generated at 1220, which may be similar to estimating motion at 1110 in
In some implementations, an interpolation point may be identified at 1230. Identifying an interpolation point may include identifying a temporal or spatial location Δ for each interpolated frame, such that the location of the interpolated frames Δ is between t and t+1.
In some implementations, candidate interpolation motion vectors may be generated at 1240. Generating candidate interpolation motion vectors may include generating a hit list as shown in
In some implementations, an interpolation motion vector may be selected at 1250. Selecting an interpolation motion vector may include initializing output information as shown in
In some implementations, an interpolated frame may be generated at 1260. Generating the interpolated frame may include building an interpolated frame as shown in
Other implementations of the diagram of pull frame interpolation as shown in
Pull frame interpolation, or any portion thereof, can be implemented in a device, such as the computing device 100 shown in
The words “example” or “exemplary” are used herein to mean serving as an example, instance, or illustration. Any aspect or design described herein as “example” or “exemplary” is not necessarily to be construed as preferred or advantageous over other aspects or designs. Rather, use of the words “example” or “exemplary” is intended to present concepts in a concrete fashion. As used in this application, the term “or” is intended to mean an inclusive “or” rather than an exclusive “or”. That is, unless specified otherwise, or clear from context, “X includes A or B” is intended to mean any of the natural inclusive permutations. That is, if X includes A; X includes B; or X includes both A and B, then “X includes A or B” is satisfied under any of the foregoing instances. In addition, the articles “a” and “an” as used in this application and the appended claims should generally be construed to mean “one or more” unless specified otherwise or clear from context to be directed to a singular form. Moreover, use of the term “an embodiment” or “one embodiment” or “an implementation” or “one implementation” throughout is not intended to mean the same embodiment or implementation unless described as such. As used herein, the terms “determine” and “identify”, or any variations thereof, includes selecting, ascertaining, computing, looking up, receiving, determining, establishing, obtaining, or otherwise identifying or determining in any manner whatsoever using one or more of the devices shown in
Further, for simplicity of explanation, although the figures and descriptions herein may include sequences or series of steps or stages, elements of the methods disclosed herein can occur in various orders and/or concurrently. Additionally, elements of the methods disclosed herein may occur with other elements not explicitly presented and described herein. Furthermore, not all elements of the methods described herein may be required to implement a method in accordance with the disclosed subject matter.
The implementations of encoding, decoding, and frame interpolation described herein illustrate some exemplary frame interpolation techniques. However, it is to be understood that encoding and decoding, as those terms are used herein may include compression, decompression, transformation, or any other processing or change of data, and that the terms frame interpolation and pull frame interpolation, as those terms are used herein, may include generating one or more new frames between two original frames, such that the new frame depicts content at a time or space not captured by the original frames.
The implementations of the transmitting station 100A and/or the receiving station 100B (and the algorithms, methods, instructions, etc. stored thereon and/or executed thereby) can be realized in hardware, software, or any combination thereof. The hardware can include, for example, computers, intellectual property (IP) cores, application-specific integrated circuits (ASICs), programmable logic arrays, optical processors, programmable logic controllers, microcode, microcontrollers, servers, microprocessors, digital signal processors or any other suitable circuit. In the claims, the term “processor” should be understood as encompassing any of the foregoing hardware, either singly or in combination. The terms “signal” and “data” are used interchangeably. Further, portions of the transmitting station 100A and the receiving station 100B do not necessarily have to be implemented in the same manner.
Further, in one implementation, for example, the transmitting station 100A or the receiving station 100B can be implemented using a general purpose computer or general purpose/processor with a computer program that, when executed, carries out any of the respective methods, algorithms and/or instructions described herein. In addition or alternatively, for example, a special purpose computer/processor can be utilized which can contain specialized hardware for carrying out any of the methods, algorithms, or instructions described herein.
The transmitting station 100A and receiving station 100B can, for example, be implemented on computers in a real-time video system. Alternatively, the transmitting station 100A can be implemented on a server and the receiving station 100B can be implemented on a device separate from the server, such as a hand-held communications device. In this instance, the transmitting station 100A can encode content using an encoder 400 into an encoded video signal and transmit the encoded video signal to the communications device. In turn, the communications device can then decode the encoded video signal using a decoder 500. Alternatively, the communications device can decode content stored locally on the communications device, for example, content that was not transmitted by the transmitting station 100A. Other suitable transmitting station 100A and receiving station 100B implementation schemes are available. For example, the receiving station 100B can be a generally stationary personal computer rather than a portable communications device and/or a device including an encoder 400 may also include a decoder 500.
Further, all or a portion of implementations can take the form of a computer program product accessible from, for example, a tangible computer-usable or computer-readable medium. A computer-usable or computer-readable medium can be any device that can, for example, tangibly contain, store, communicate, or transport the program for use by or in connection with any processor. The medium can be, for example, an electronic, magnetic, optical, electromagnetic, or a semiconductor device. Other suitable mediums are also available.
The above-described implementations have been described in order to allow easy understanding of the application are not limiting. On the contrary, the application covers various modifications and equivalent arrangements included within the scope of the appended claims, which scope is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structure as is permitted under the law.
Claims
1. A method comprising:
- identifying a plurality of input video frames;
- generating a plurality of motion vectors indicating motion from a first frame of the plurality of input video frames to a second frame of the plurality of input video frames;
- identifying an interpolation point between the first frame and the second frame;
- generating a plurality of candidate interpolation motion vectors indicating motion from the first frame to the interpolation point and from the second frame to the interpolation point based on the plurality of motion vectors;
- selecting an interpolation motion vector from the plurality of candidate interpolation motion vectors based on a metric; and
- generating an interpolated frame at the interpolation point based on the selected interpolation motion vector.
2. The method of claim 1, wherein selecting the interpolation motion vector is based on smoothness constraints within the interpolated frame.
3. The method of claim 1, wherein selecting the interpolation motion vector is based on smoothness constraints between the first frame and the second frame.
4. The method of claim 1, wherein the plurality of input video frames includes an input video temporal sequence such that the first frame represents a first time in the input video temporal sequence and the second frame represents a second time in the input video temporal sequence, wherein the first time is adjacent to the second time in the input video temporal sequence, and wherein the interpolation point indicates a time between the first time and the second time.
5. The method of claim 1, wherein the plurality of input video frames includes an input video spatial sequence such that the first frame includes content captured from a first angle in the input video spatial sequence and the second frame includes content captured from a second angle in the input video spatial sequence, wherein the first angle is adjacent to the second angle in the input video spatial sequence, and wherein the interpolation point indicates a third angle between the first angle and the second angle.
6. The method of claim 1, wherein the interpolated frame includes a plurality of interpolation sites and wherein selecting the interpolation motion vector includes iteratively, for each interpolation site in the plurality of interpolation sites, selecting an interpolation motion vector and updating the interpolated frame based on the selected interpolation motion vector.
7. The method of claim 1, wherein generating the plurality of candidate interpolation motion vectors includes generating a candidate interpolation motion vector based on motion prediction for a current interpolation site and motion prediction for a plurality of adjacent sites.
8. The method of claim 1, wherein generating the interpolation frame includes generating a plurality of interpolation pixels, and wherein selecting the interpolation motion vector includes selecting an interpolation motion field including a plurality of interpolation motion vectors, wherein each interpolation motion vector in the plurality of interpolation motion vectors is associated with an interpolation pixel in the plurality of interpolation pixels.
9. The method of claim 8, wherein generating the interpolated frame includes correcting an artifact in the interpolated frame based on the interpolation motion field.
10. The method of claim 9, wherein correcting the artifact includes blending the interpolated frame with an average of the first frame and the second frame, wherein the degree of blending is based on a gradient of the motion field.
11. The method of claim 10, wherein blending the interpolated frame includes:
- replacing a portion of the interpolated frame that has a high motion gradient with a corresponding area of the average of the first frame and the second frame, and
- keeping a portion of the interpolated frame that has a low motion gradient.
12. The method of claim 1, wherein generating the plurality of motion vectors includes determining a degree of smoothness of the plurality of motion vectors, the method further comprising:
- using the first frame or the second frame as the interpolated frame on a condition that the degree of smoothness is above a threshold.
13. The method of claim 1, wherein generating the plurality of candidate interpolation motion vectors, selecting the interpolation motion vector, and generating the interpolated frame are performed iteratively at a course resolution that is lower than a target output resolution and at a fine resolution that is equal to the target output resolution.
14. The method of claim 13, wherein generating the plurality of candidate interpolation motion vectors, selecting the interpolation motion vector, and generating the interpolated frame at the course resolution includes using a block based motion field and wherein generating the plurality of candidate interpolation motion vectors, selecting the interpolation motion vector, and generating the interpolated frame at the fine resolution includes using a higher resolution block based motion field or a pixel based motion field.
15. The method of claim 1, wherein generating the plurality of candidate interpolation motion vectors include identifying an occlusion at the interpolation point.
16. The method of claim 15, wherein generating the plurality of candidate interpolation motion vectors and identifying the occlusion are performed jointly with a combined energy function.
17. The method of claim 1, wherein generating the plurality of motion vectors includes generating motion vectors indicating motion between a third frame of the plurality of input video frames and the first frame, and between the second frame and a fourth frame of the plurality of input video frames.
18. A method comprising:
- identifying a plurality of input video frames;
- generating a plurality of motion vectors indicating motion from a first frame of the plurality of input video frames to a second frame of the plurality of input video frames;
- determining a degree of smoothness of the plurality of motion vectors;
- using the first frame or the second frame as the interpolated frame on a condition that the degree of smoothness is above a threshold; and
- on a condition that the degree of smoothness is within the threshold, performing pull frame interpolation by: identifying an interpolation point between the first frame and the second frame; jointly, using a combined energy function, identifying an occlusion and generating, based on the plurality of motion vectors, a plurality of candidate interpolation motion vectors that includes: a candidate interpolation motion vectors indicating motion from the first frame to the interpolation point, a candidate interpolation motion vectors indicating motion from the second frame to the interpolation point, and a candidate interpolation motion vector based on motion prediction for a plurality of adjacent sites; for each interpolation site in a plurality of interpolation sites, selecting an interpolation motion vector from the plurality of candidate interpolation motion vectors based on smoothness constraints within the interpolated frame and on smoothness constraints between the first frame and the second frame selecting an interpolation motion vector and updating the interpolated frame based on the selected interpolation motion vector; and generating an interpolated frame at the interpolation point based on the selected interpolation motion vector, wherein the interpolated frame includes the plurality of interpolation sites, wherein generating the interpolated frame includes: correcting an artifact in the interpolated frame based on the interpolation motion vector by blending the interpolated frame with an average of the first frame and the second frame, wherein the degree of blending is based on a gradient of a motion field associated with the interpolation motion vector, such that a portion of the interpolated frame that has a high motion gradient is replaced with a corresponding area of the average of the first frame and the second frame.
19. The method of claim 18, wherein the plurality of input video frames includes an input video temporal sequence such that the first frame represents a first time in the input video temporal sequence and the second frame represents a second time in the input video temporal sequence, wherein the first time is adjacent to the second time in the input video temporal sequence, and wherein the interpolation point indicates a time between the first time and the second time.
20. The method of claim 18, wherein the plurality of input video frames includes an input video spatial sequence such that the first frame includes content captured from a first angle in the input video spatial sequence and the second frame includes content captured from a second angle in the input video spatial sequence, wherein the first angle is adjacent to the second angle in the input video spatial sequence, and wherein the interpolation point indicates a third angle between the first angle and the second angle.
21. The method of claim 18, wherein generating the plurality of candidate interpolation motion vectors, selecting the interpolation motion vector, and generating the interpolated frame are performed iteratively at a course resolution that is lower than a target output resolution and at a fine resolution that is equal to the target output resolution.
22. The method of claim 21, wherein generating the plurality of candidate interpolation motion vectors, selecting the interpolation motion vector, and generating the interpolated frame at the course resolution includes using a block based motion field and wherein generating the plurality of candidate interpolation motion vectors, selecting the interpolation motion vector, and generating the interpolated frame at the fine resolution includes using a higher resolution block based motion field or a pixel based motion field.
Type: Application
Filed: Mar 29, 2013
Publication Date: Oct 2, 2014
Patent Grant number: 9300906
Inventors: Anil Kokaram (Sunnyvale, CA), Damien Kelly (Sunnyvale, CA), Andrew Joseph Crawford (Mountain View, CA)
Application Number: 13/853,354
International Classification: G06T 3/40 (20060101); G06T 5/50 (20060101);